This is implementation of BlockReentrancy()
protected IDisposable BlockReentrancy()
{
this._monitor.Enter();
return this._monitor;
}
There is another method CheckReentrancy()
protected void CheckReentrancy()
{
if ((this._monitor.Busy && (this.CollectionChanged != null)) && (this.CollectionChanged.GetInvocationList().Length > 1))
{
throw new InvalidOperationException(SR.GetString("ObservableCollectionReentrancyNotAllowed"));
}
}
Such methods as ClearItems
, InsertItem
, MoveItem
, RemoveItem
, SetItem
check CheckReentrancy()
before modifying collection.
So the code below guarantees that collection will not be changed inside of using
, but only if there is more than one handler subscribed to CollectionChanged
event.
using BlockReentrancy())
{
CollectionChanged(this, e);
}
This example demonstrates effect of BlockReentrancy()
private static void Main()
{
collection.CollectionChanged += CollectionCollectionChanged1;
collection.CollectionChanged += CollectionCollectionChanged2;
collection.Add(1);
}
private static void CollectionCollectionChanged1(object sender, NotifyCollectionChangedEventArgs e)
{
collection.Add(2); // this line will throw exception
}
private static void CollectionCollectionChanged2(object sender, NotifyCollectionChangedEventArgs e)
{
}
BlockReëntrancy
using (BlockReentrancy()) {}
is also required in multi-threaded use case when collection is being updated so frequently that it interferes with theOnCollectionChanged
processing. This can potentially happen with just a single XAML binding and without any additional explicit subscribers in the custom code.